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LUMINOSITY MEASUREMENT AT ILC I. Bozovic -Jelisavcic (on behalf of the FCAL Collaboration)

LUMINOSITY MEASUREMENT AT ILC I. Bozovic -Jelisavcic (on behalf of the FCAL Collaboration) Vinca Institute of Nuclear Sciences Belgrade, Serbia. FCAL Collaboration. National Center of Particle & HEP, Minsk, Belarus LAL Orsay, France Royal Holloway University of London, Great Britain

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LUMINOSITY MEASUREMENT AT ILC I. Bozovic -Jelisavcic (on behalf of the FCAL Collaboration)

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  1. LUMINOSITY MEASUREMENT AT ILC I. Bozovic-Jelisavcic (on behalf of the FCAL Collaboration) Vinca Institute of Nuclear Sciences Belgrade, Serbia

  2. FCAL Collaboration National Center of Particle & HEP, Minsk, Belarus LAL Orsay, France Royal Holloway University of London, Great Britain DESY, Hamburg & Zeuthen, Germany Tel Aviv University, Israel KEK, Japan Tohoku University, Japan AGH University, Krakow, Poland Jagiellonian University, Krakow, Poland Institute of Nuclear Physics, Krakow, Poland University of Warsaw, Warsaw, Poland Joint Institute Nuclear Research, Dubna, Russia IFIN-HH Bucharest, Romania VINCA Inst. of Nuclear Science, Belgrade, Serbia CERN, Switzerland Argonne National Lab, Upton, USA University of Colorado, Boulder, USA University of Santa Cruz, USA SLAC, USA Institutes contributing to LumiCal related studies

  3. Luminometer at ILC

  4. LumiCal simulation study LumiCal fiducial volume 2.1 nb integrated x-sec. Stable sampling term vs. shower energy Intergrated deposited E vs. E shower Esh [GeV] Esh [GeV]

  5. Luminosity measurement Integrated luminosity can be determined from the total number of Bhabha events produced in the acceptance region/fiducial volume of the luminosity calorimeter and the corresponding theoretical cross-section IT IS COUNTING EXPERIMENT, BUT... real experiment 1. To build a device capable of precise reconstruction of E,  2. To control (other) systematics Event selection the polar angle of the reconstructed shower must be within the detector fiducial volume at one side and within at the other. total energy deposited in the LumiCal must be more than 80% of the center-of-mass energy

  6. Luminosity measurement SYSTEMATIC EFFECTS TO BUILD A DEVICE…  reconstruction Shower develops under a non-zero angle with respect to the probing geometry  bias in luminosity measurement  =3.2∙10-6 rad

  7. More systematics TO BUILD A DEVICE… Energy resolution control of the sampling term E (also called _res at slide 4) , or 25% for OTHER SOURCES OF SYSTEMATICS 2- background High x-sec  10s nb, spectators close to the beam pipe

  8. More systematics However, less than 1% of spectators in the LumiCal B/S ratio saturates within the same order of magnitude at ILC energies B/S=2.3 10-3 at 500 GeV and B/S = 5.2 10-3 at 1 TeV Sensitivity of background to signal ratio to systematic effects that may come from the uncertainty of detector fiducial volume due to various detector displacements is negligible

  9. More systematics Background hits on the front plane before and after selection applied Space charge effects Beam-beam interactions Modification of initial state: Beamstrahlung√s’≤√s, ini≠ 0, Eelec≠ Eposit Modification of final state: Electromagnetic deflection  Bhabha angle reduction (~10-2mrad) + small energy losses Total BHabha Suppression Effect (BHSE) ~1.5%

  10. More systematics Simulation of BHSE measurement Data-driven method from reconstructed luminosity spectrum by measuring angles in the LumiCal Dominant effect comes from beamstrahlung BS+EM BS NO BHSE BHSE from BS can be exp. measured and treated as a bias However, to provide (BHSE) ~0.4%(0.1%) beam parameters x and zhave to be known within 20%(5%). Impact of beam-beam effects on precision luminosity measurements at the ILC, C. Rimbault et al., JINST 2:P09001,2007

  11. More systematics SUMMARY ON SYSTEMATICS Bunch width variation for ±100 nm around nominal value x=655 nm • Test beam studies are needed to determine experimental uncertainties of effects that should be taken as corrections (i.e. bias in polar angle). • Precision determination of Bhabha energy and understanding of detector energy resolution is necessary due to the applied selection. • NLO calculations at ILC energies are needed both for Bhabha and background processes. • Dominant effects come from beam-beam interaction (BHSE) and 2- processes. Both can be corrected for. In BHSE case the correction is large and require beam parameter control at 20% level or better (BS component), while uncertainty in physics background comes from the error on x-section. x=755 nm x=555 nm

  12. Total systematics TOTAL SYSTEMATICS at 500 GeV * Upper limit – the size of effect is taken as uncertainty. ** Uncertainty of the theoretical cross-section for Bhabha at LEP energies [OPAL, G. Abiendi et al., Eur. Phys. J C14(2000)373]. *** 5% control of bunch x and z sizes.

  13. Summary • It has been proven through simulation that it is possible to design luminometer at ILC capable of precision reconstruction of Bhabha energy and polar angle. • Numerous systematic effects are present and understood (again) at the level of simulation. They amount to 2.8∙10-3 systematic uncertainty in luminosity at the upper limit, with the statistical error on luminosity less than 10-3 needed for integrated annual luminosity at high energies. • Most of systematic effects can be taken as corrections once their experimental (test-beam) or theoretical uncertainties are known. • The largest contribution to the relative error on luminosity comes from collective (beam-beam) effects and physics background. According to the present knowledge, beam-beam effects can not be reduced below 10-3 (even if bunch size is controlled at 5% level). However, it doesn’t relax the need for detector precision.

  14. To do list • Sensitivity of the luminosity measurement to changes of the detector fiducial volume implies importance of mechanics and position control of the LumiCal (inner radius, various radial displacements, F-B relative positions, etc.). It is needed to quantify impact of these effects on luminosity measurements within the current detector geometry, as well as to prove in situ mechanical control. • Test-beam studies are needed to understand experimental uncertainties of some effects (i.e. realistic calibration procedure). • Space charge effects introduce error in luminosity measurement of order of 10-3. They have to be studied in more details with respect to changes in geometry and at all ILC energies*. • Finally, for the reason of completeness, theoretical uncertainties at the NLO level are needed for Bhabha and background processes at ILC energies*. • Final choice of shape and material of the beam-pipe has to be simulated to estimate impact of pre-showering on luminosity measurement. For parallel vs. conical beryllium pipe the effect is estimated to be O(10-4). • * the same is true for CLIC

  15. BACKUP

  16. Mechanical issues Systematic impact on luminosity measurement All by A.Stahl, old geometry [26,82] mrad, 3,05 m from IP • IN SITU • LPS prototype monitors LumiCal as a whole object • Obtained accuracy 0.5m in the X-Y plane and 1.5m in z direction – order of magnitude better than required • Method for measuring displacement of individual sensor layers/inner radius under study 4 m for L/L~10-4, ~40 m for L/L~10-3 100 m for L/L~10-4, ~ 1.5 mm for L/L~10-3 Error in half-

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